DE2338621B2 - CIRCUIT ARRANGEMENT FOR THE INSERTION OF PULSES WITH DEFINED EDGE DURATION IN A TELEVISION SIGNAL - Google Patents

Description

The invention relates to a circuit arrangement for the onset of pulses with a defined Edge duration in a television image signal, particularly in a television camera apparatus.

In television, the picture signal is in periodically occurring horizontal periods by one in one TV camera existing recorder, z. B. a pickup tube supplied. In a large part one Horizontal period is given the video information or the picture content, and the remaining smaller part becomes for the. Horizontal rewind used to the beginning of a subsequent line. In the horizontal return time noise signals and mostly large spurious signal peaks occur in the output signal. To the Removal of unwanted throbbing and interference signal peaks and for precise definition of the beginning and the end of the horizontal retrace time with the videoin formation, a horizontal blanking pulse is used in every television system. This horizontal blanking signal results on the one hand that the distant interference signal peaks the further signal processing in the camera do not affect, and on the other hand that in the horizontal blanking time a horizontal sync pulse and optionally the color synchronizing signal in the case of color television for transmission to a display device can be added to the image signal. In a video signal constructed in this way, the different times have been set according to the television season, with a small one anterior or larger posterior black shoulder by the time difference between the leading edge of the Horizontal blanking and the horizontal sync pulse or between the trailing edge of the sync and Blanking pulse it is determined in which back porch in a fixed manner the Color sync signal is applied.

The normally performed addition of a horizontal blanking pulse to the image signal can be done with compare to opening a switch via which the Bildsigna! let through in the rest of the horizontal period will. In practice, this includes a leading edge of the pulse in the transmitted image signal, which edge has a tendency caused by the interruption speed of the electronically designed switch is determined. In practice, times of around 10 ns can be used for this edge duration (switching duration) appear. To remove the above-mentioned interference signal peaks, it is beneficial to open the switch to be done as quickly as possible so that these peaks

^ cannot exert any influence during opening. When the switch is closed, essentially the entire electronic circuit and the image signal value currently offered is the duration of the

Pulse trailing edge. In practice it turns out that Times of 15 to 20 ns occur.

With the RTMA television standard, the edge times of the horizontal synchronous and blanking pulses are taken into account, and it was agreed that these must be less than four Thousands of a horizontal period, which is about 250 ns The edge duration of the blanking pulse is for a standardized signal amplitude between a minimum value given as a black level and a maximum value as a so-called maximum white value, where as Edge duration is considered to be the time between one tenth and nine tenths of the change in amplitude will. The same applies to a standardized amplitude of the Horizontal sync pulses.

It turns out that the values of the edge duration occurring in practice are actually too short. The result is that the signal processing circuitry following the switch mentioned has a steep, high leading edge, for example the blanking pulse, must process the normal and stray capacitive Couplings affect signal processing. The maximum white value occurs at the beginning of the horizontal casting in the image signal, the steep high trailing edge of the horizontal blanking pulse becomes an overshoot trigger with all resulting therefrom for signal processing and playback Follow.

The steep signal edges described are to be used in particular for proper functioning Signal filter and disadvantageous in signal processing with the aid of image recording devices.

With the CCIR television standard, it is therefore a requirement to choose the pulse edge duration of the horizontal synchronous and blanking pulses between 200 and 400 ns.

To this end, a more or less steep-edged square-wave pulse is added during the blanking time, so that the interfering signal components are shifted to high level values; then this impulse is limited or cut off to the desired level of utilization, so that the interfering signal parts are cut off. The edge duration can be extended by RC-Geder to such an extent that the values prescribed by the standard are adhered to; Otherwise, the course of the pulse edges is not more precisely defined, especially since the edge also depends on the respective signal, which is included as an additive.

The invention is based on the object of creating a circuit arrangement by means of which a horizontal blanking or a horizontal synchronizing pulse with a defined edge profile is used in a television picture signal, which is largely independent of specific influences of the components, in particular the stray capacitances of the circuit and from signal sales. A circuit arrangement of the type mentioned at the outset has the identifier for this purpose. that in a (first) signal converter a blanking or sync pulse is formed which assumes a first value in a first time range and a second value (ground potential 0) in a second time range and which takes on between the first and second time ranges and between the second and the first time range each defined to the desired extent over a certain period of time,?. B. linearly increasing or decreasing. Has edge, and that this blanking or sync pulse is inserted into the television picture signal by means of a signal comparison circuit such that the television picture signal is replaced by the blanking pulse or the blanking pulse by the television picture signal as soon as the linear edge of the blanking or sync pulse the value of the television picture signal exceeds or falls below
An embodiment of the invention is shown in the drawings and is described in more detail below. It shows

F i g. 1 shows an embodiment; one according to the invention Circuit arrangement suitable for introducing

ίο horizontal blanking pulses in an image signal, and

2 shows some signals occurring therein to explain the mode of operation of the circuit arrangement according to FIG. 1.
In the circuit arrangement according to FIG. 1, 1 is an input of the circuit arrangement to which a signal A is fed. In Fig. 2, the signal A is plotted as a function of time with a pulse with a duration Ti. Signal A is a horizontal blanking signal. which occurs periodically in every horizontal period of, for example, 63.55 or 64 µs. The horizontal periods are given as they have been prescribed in accordance with the RTMA or CCIR standard. The pulse duration 7Ä is as prescribed in a television standard, but the pulse, as it will turn out, occurs somewhat shifted in time. The pulse shown in signal A with a duration 7i, of approximately 11 to 12 ps, has a steep leading edge starting from ground potential 0 at a point in time fa up to a voltage value + V _A of, for example, 1.5 V. At a point in time u , this also occurs steep trailing edge. The duration of the edges at times ίο and U is in that in FIG. 2 illustrated signal A not been taken into account, but is considered to illustrate that the slope times for example, only be about 10 ns.

In the case of the signals A through G shown in FIG. 2, to. U ti denotes some successively occurring points in time.

Normally, the signal A shown in Fig. 2, with a pulse slightly shifted in time, is used to insert the horizontal blanking pulses into a television picture signal. In FIG. 2, a signal £ em indicates a possible image signal supplied by a pick-up (e.g. a pick-up tube) in a television camera. The so-called maximum white value is indicated by + W in signal E, which is, for example, 200 mV in a standardized manner, while the black level is at ground potential 0. The Signa! E from FIG. 2 occurs in the circuit arrangement according to FIG. 1 at an input 2 of a signal processing circuit 3. The signal processing circuit 3 is shown in a schematic manner with an on -off switch 4 connected to the input 2 and an (inverting) amplifier 5 connected downstream of it. The switch 4 is actuated in accordance with a pulse D to be described in more detail with undefined steep edges.

In the circuit arrangement according to FIG. 1, the input 1 is connected to a signal converter 6, which converts the signal A supplied to it into FIG. 2 shown signal B or B ' derives which Signa! B 'is available at a first output 7. A pulse shaper 8, which forms part of the signal converter 6, converts the supplied signal ßum into a signal Oind supplies a signal L to control the switch 4 at a second output 9. Signal D shown in 2 thus contains a modified pulse with undefined steep edges, which in more or less shifted points in time (h and fs)

ju υ

occur above the edges in signal A (to and b).

From the output 7 of the signal converter 6, the signal B ' arrives at an input IO of a signal comparison circuit 11, to the second input 12 of which the signal G is fed. An output 13 of the signal comparison circuit U is connected to a control input 14 of a feedback circuit 16 incorporated in an amplifier circuit 15. The input 17 of the amplifier circuit 15 is connected to an output 18 of the signal processing circuit 3, while an output 19 of the amplifier circuit 15 carries the signal G. The output 19 is at the same time the output of the circuit according to the invention, which with the signal G of FIG. 2 results in a television picture signal with a horizontal blanking pulse with a defined pulse edge duration. is

To explain the mode of operation of the circuit arrangement according to FIG. 1, the following applies: The input 1 in the signal converter 6 is connected to the base of a transistor 20 , while the base and the emitter are connected to ground via a resistor 21 and 22, respectively. The collector of the transistor 20 is connected directly to the base of a transistor 23 and via a resistor 24 to the cathode of a diode 25, the anode of which is at a voltage + Vi. The collector of transistor 23 is directly connected to the voltage + Vi, and the emitter is connected to a voltage - Vi via a resistor 26. The emitter of transistor 23 is connected to one terminal of an electrolytic capacitor 27, the other terminal of which is connected to the cathode of diode 25 Between the collector of the transistor 20 and ground there is a capacitor 28. For the capacitor 28, the parts 20 to 27 inclusive as a current source (20-27) are effective in a manner to be described, which under control of the signal A for a certain time Capacitor C ₂ S delivers a constant charge or discharge current. The emitter of the transistor 23 thereby leads to the action shown in FIG. Signal B shown in FIG. 2, which at the connection point of two resistors 29 and 30 arranged in series with respect to ground gives the signal B'zn to the output 7 connected to it

To explain the mode of operation of the current source (20-27) , it is assumed that the capacitor 27 with a large capacitance carries a certain bias voltage which is set to a value that is slightly smaller than + Vi- Vbe- voltage Vbe is the voltage drop, for example 0.7 V, which is present in the conductive state at the base-emitter diode of a transistor (23) and at the anode-cathode junction of a diode (25). 2 it is indicated that the ground potential is present in signal A and the voltage + Vl of, for example, 6 V in signal B before time ίο. In FIG. 1 the transistor 20 blocked while at the base of the conductive transistor 23 the voltage + Vi plus the voltage V _B e is present on the base-Enritter diode, which voltage + Vi + Vbeauch is on the capacitor 28. The bias voltage on the capacitor 27 to the voltage + V, added at the emitter of the transistor 23, results in the current-djffch the resistance 2 * when the diode 25 is blocked.

At the time fc occurs in the Signa! A according to FIG. 2 the voltage + Va on, the transistor 20 becomes conductive, it IUeBt enter control of the constant voltage

Immediately after the point in time ft, resistor 24 carries a current i. With ÜBfe of the resistors 2t tmd ^ the AÄehsponkt of the transistor 20 is determined such that immediately after the point in time fo the voltage + Va at the base results in an emitter current / 22 = 2ij4. The result is that the capacitor 28 is discharged via the transistor 20 with a current of the size of / 24. The voltage drop brought about by this at the capacitor 28 also occurs at the emitter of the (emitter follower) transistor 23, which voltage drop is passed on via the capacitor 27 to the connection point between the resistor 24 and the blocked diode 25. Consequently, the current flowing through the resistor 24 * ₂ 4 remains constant, and capacitor 28 is / «discharged in accordance with a constant current. The discharge continues until the collector voltage of the transistor 20 has dropped so far that it absorbs the current flowing in from the resistor 24, so that there is no longer any discharge current available for the capacitor 28. Since the base voltage of the transistor 20 is 1.5 V due to the signal A , the emitter voltage at the resistor 20 is approximately 0.8 V, and the aforementioned decrease in the collector current occurs when the collector voltage, which is also the voltage across the capacitor 28, is approximately Has reached 0.9 V. This voltage is also applied to the base of the transistor 23, and the signal B at the emitter of the transistor 23 then has a value of approximately 0.2 V which is lower by Vbe , that is to say approximately ground potential.

The discharging of the capacitor 28 with the constant current of the current source (20-27) results in the signal B according to FIG. 2 the linear edge shown between the times fo and h. Since the bias voltage mentioned on the capacitor 27 is somewhat smaller than + Vi Vbe. where at the time fo the cathode of the diode 25 is impressed with a voltage that is slightly less than + 2 V, - V _B e, the voltage at the cathode of the diode 25 will want to be slightly less than + Vi just before the time f ₃ - V _{e £} , which is avoided by the diode 25 becoming conductive. The voltage across the capacitor 27 is brought to + Vi Vet. The constant voltage + V _A at the base of the transistor 20 keeps: after the point in time f _} the current / 22 constant and thus also the current ht corresponding to it.

In signal A according to FIG. it is indicated that the voltage + V _A ceases to exist at the time U at the end of the horizontal blanking time T _b. As a result, the transistor 20 is blocked. The current tu flowing through the resistor 24 will now charge the capacitor 28, and the voltage increase is fed back via the transistor 23 and the capacitor 27 to the connection point of the resistor 24 and the diode 25, which is immediately blocked cause the charge current in constant is the charging current corresponding to the discharge, and indeed in that in the discharge, the condition is yes = 2 £ «fulfilled the charging of the capacitor 28 is thus a specified when signal B according to Figure 2 duration of U to £ claim, which then corresponds to the duration% to & Immediately after the time & the emitter tfeS transistor 23 has the voltage + Vj, zn which the voltage * on the capacitor 27 of + V, - Vbe is inserted, so that the cathode of the diode 25 is impressed, the voltage Vbe + 2Vi- gets as iur the Z hV point to be described, then the power ffießt "* übet Wt KoBektordiode base of the transistor 23 to be vöt Daderch the voltage across the capacitor M decreases somewhat, up to the next perit><Ssct

3 5711

Zo So

occurring time ίο. In the manner described, the following periodically occurring pulses (not shown) in signal A result in associated pulse edges in signal B as in FIG. 2 shown.

The signal B 'is obtained via the voltage divider with the resistors 29 and 30 , which together with a signal F' = aF in FIG. 2 is applied. The signal B ' has a fluctuation between the ground potential 0 and a voltage + Ve.

A pulse shaper 8 is received in the signal converter 6 in order to derive the signal D from the signal B. For this purpose, the emitter of the transistor 23 is connected to the base of a transistor 31, the emitter and collector of which are connected via a resistor 32 or

33 is connected to the voltage + V or - V. The collector of the transistor 31 thereby leads to the in FIG. Signal C shown in FIG. 2, which has a voltage - Vi, when the transistor 31 is blocked and in its maximally conductive state, between times tj and u, has a positive voltage of 100 mV. The pulse shaper 8 is designed with a threshold circuit which is made up of two transistors 34 and 35, the interconnected emitter electrodes of which are connected to the voltage - Vi via a resistor 36, while the collector of the transistor

34 or 35 is applied directly or via a resistor 37 to the voltage + V _t . Since the base of the transistor «; 35 is connected to ground, the signal C fed to the base of transistor 34, when ground potential 0 is exceeded from the negative voltage, will block the previously conductive transistor 35 at time t ₂ , which is a few ns (5 to 10) before dun Time f ₃ is, this will be done. Thus, at time fs, which is a few ns behind time U , transistor 35 will become conductive again. The result is that the collector of transistor 35 in threshold circuit (34-37) carries signal D shown in FIG. which is available at output 9. By choosing the resistors 36 and 37 it has been achieved that before the time t ₂ and after the time fs the collector of the transistor 35 carries the ground potential,

^ like this in F i g. 2 is shown; however this is not

"" wefentiicn.

The signal D at the output 9 is fed to the signal processing circuit 3 and controls the in FIG. 1 the electronic switch 4.

When the signal D is activated, the on / off switch 4 lets part of the signal E supplied to it through. From the example shown in Fig. 2 signal E shows that the video information received from a not-shown pickup to in the time interval T _b is present case related Störsignalsprtzen in S ^ occur nal skin in the huervgü Tb noise signals and the horizontal retrace Signal E is specified with the voltage + Vw of the maximum white value, which has, for example, the standardized value of 20OmV. The designated by F, passed by the switch 4 signal to blows as such in Fig. 2 dargesteBt, but a so überemsümmendes verstirictes signal F = aF. The maximum white value + aVw is applied to Demseend.

The signal F = aF shown in FIG. 2 would appear at the output 19 in FIG. 1 if the general sleicfing circuit 11 were not effective. The amplifier SÄfertaänaich after the factor <-1) the signal F »Ä

Double room

reverse polarity, which is amplified by the amplifier circuit 15 with the (then regarded as unchangeable) feedback circuit 16 with a factor (- a) . The signal F ' = aF according to F i g. 2 has steep edges of 10 to 20 ns at times t ₂ and f _5. The leading edge at time t ₂ does not cause the circuit any difficulties at this point, but these will definitely occur during further signal processing, in particular when filters are used.

According to the invention, the output 19 is not what is shown in FIG. 2 illustrated signal F '= aF be issued, but the signal represented by the signal G. ß'der signal comparison circuit 11, and that the base is supplied to a transistor 38, whose collector via a resistor 39 to the voltage - is _V1. The emitter of transistor 38 is connected to the emitter of transistor 40 and both are across a resistor

41 at the voltage + Vi. The base of the transistor 40 is at the output 19 and the collector at the voltage - V ₁ . The connection point of the resistor 39 with the transistor 38 is at the output 13, which via the control input 14 with the gate electrode of a transistor

42 is connected. which is included in the feedback loop 16 of the amplifier circuit 15. The transistor 42 is of the insulated gate type and has source and drain electrodes in parallel with a resistor 43 are connected between the output and an inverting one Input of an operational amplifier 44. The output of the amplifier 44 forms the output 19. The not inverting input of amplifier 44 is connected to ground, while the inverting input has a Resistor 45 is at input 17.

The following applies to the mode of operation of the combination of the signal comparison circuit 11 and the amplifier circuit 15. In the blocked state, when the voltage at the base of transistor 38 is higher than that at the base of transistor 40, transistor 38 has the effect that the gate electrode of transistor 42 is at the voltage - Vi, and transistor 42 is thereby also blocked. Then the transistor 42 has an infinitely large resistance, and the gain (a) of the amplifier circuit 15 is equal to the ratio of the resistance values of the resistors 43 and 45. Thus, taking into account the signal supply to the inverting input of the amplifier 44 , the gain of the circuit 15 is (- a). From Fig. 2 shows that the signal β 'before the point in time f ₀ and after the point in time h, the voltage + V'e-which is greater than the maximum white value + aVw that can occur at the output 19. For explanation it applies that with a voltage Vw = 200 mV and a = 7.5 the voltage Vb- = 1.6 V has been selected. It follows that the signal comparison circuit 11 has no effect before the time to and after the time ti so that the signal G at the output 19 then corresponds to the described signal F = aF. The voltage at the connection point of the resistor 41 and the transistor 40 follows the eye-foul voltage values of the signal G at the output 19 without further consequences, if not by a voltage + ^ higher.

FIG. 2 shows that at time Ji the voltage in signal B ' has become equal to hn signal F = aF, i.e. b, the voltage on the base electrodes of the transistors 38imd 40 has become the same. Dadurcii wildly the transistor 38 conductive. UnnatteBwf after the point in time 4, the voltage at the base of the transistor 38 continues to decrease, while the voltage at the base of the transistor 38 continues to decrease

Ä »530/285

Transistor 40 would remain approximately the same under the influence of the signal ( -F) applied to input 17. However, this does not happen because the transistor 38 will carry more and more current with a consequently less negative voltage at the output 13, the controllable resistor (transistor 42) becoming the smaller and thus also the gain of the amplifier circuit 15, so that at the output 19 the same voltage is present as it is offered to the base of transistor 38. The signal comparison circuit 11 emits such a high voltage at the output 13 that the gain of the amplifier circuit 15 is regulated back so far that the voltage in the signal Cam output 19 cannot be higher than in the signal B '.

In the manner described .Ί is from the time until the time h 'h is the gain of the amplifier circuit 15 continues back controlled so that an edge is obtained in the signal C that is determined by the signal B'. If instead of the approximately constant voltage, as shown in the signal P = aF between the times fi and t ₂ , a voltage drop to below the eye-eye voltage occurs in the signal B ' , this value also appears in the signal G , since then the signal comparison circuit 11 turns transistor 42 off.

From the above it can be seen that regardless of the signal available at input 17, the voltage at output 19 can never exceed the voltage currently offered to input 10. It follows from the in FIG. 2 signals B ' and F' = aF that from the time U «is to the time t _b the edge in the signal Gder must correspond to the signal ^ '.

In the same way it follows that between the times h and U of the signal G with the ground potential in the signal B ' and at the non-inverting input of the amplifier 44, the gain of the amplifier circuit 15 is regulated back to zero. If, for whatever reason, a negatively directed current pulse occurs at input 17 during the time h to U , this will not occur at output 19 as a positively directed pulse due to the zero gain of amplifier circuit 15. So it is possible not to use the switch 4 in the signal processing circuit for a horizontal blanking pulse introduction into the signal E, but to feed the signal E directly to the input 17 via the inverting amplifier 5. However, since the gain zero of the amplifier circuit 15 is only effective for the positive interference signal peaks in the signal E and not for the negative peaks possibly present therein, these must first be removed via a clamping circuit. Because of the magnitude of the positive interference signal peaks, the gain must be regulated back to zero.

A less precise regulation back to zero is sufficient if in the signal E, in the manner given in FIG. 1 , but the switch 4, a switching pulse with undefined steep edges is inserted. It is favorable here that the blocking by the signal D between the times fe and i ₅ takes place, i.e. approximately at the end of the trailing edge and at the beginning of the rising, defined edge, which is the result of the signal S, S '

In the case of the OaR-None, the measurement of the pulse duration of the horizontal pin to 50% of the signal amplitude between the black level and the maximum value sets FBr the signal shown in FIG

The middle between the times ίο and tj up to the middle of the times U and U must be calculated, which pulse duration must lie within 12.05 ± 0.25 μ $. Since it was recommended to use the pulse edge duration

s between 200 and 400 ns has been selected for the duration 7 about 300 ns. It follows from this that the pulse edge in signal A at time ίο must be about! 50n earlier than that of the horizontal blanking pulse prescribed in the standard.

ίο For the RTMA standard applies that with reference to signal G in F i g. 2 the time between the leading and trailing edge of the horizontal blanking pulse at 90% of the maximum value is less than 18% of the horizontal period or equal to 18% and at 10% de!

Maximum value must be greater than or equal to 16.5% of the horizontal period. With the horizontal period before 63.55 \ is , times of 11.44 \ i% or 10.49 μ5 follow. Since the pulse edge times must be less than or equal to 0.4% of the horizontal period or about 250 ns, 200 ns can be selected for the time duration T _d. The circuit arrangement shown in FIG. 1 can easily be made suitable for use in one or the other standard with an edge duration of 300 ns or 200 ns by adapting the capacitance of the capacitor 28.

In the above, for the signals B ' and F' = aF according to F i g. 2 described that the signal at the output 19 and at the input 12 of FIG. 1 can never be more positive than that of the input 10

is fed. In the case of the image signal change that normally occurs in the signal F ' between the maximum white value + aVw and the black level 0 (in the image content before time i ₀ and after time Ir) , the voltage + V _{fl is selected} as + aV _w

the signal comparison circuit 11 is not effective. If, however, a signal part exceeding the maximum white value + aVw and the voltage + V _B wanted to appear in the image content, the signal comparison circuit 11 becomes effective and is then available as a so-called white (signal) -ab-

cutting arrangement effective.

In Fig. 1, transistor 42 is of the insulated gate type as a variable resistor Feedback loop 16 has been used. Any other adjustable resistor can be used

possible. It should be mentioned that the control characteristic of the controllable resistor (42) is the effective back regulation the gain of the amplifier circuit 15 is not influenced, since with the aid of the signal comparison circuit 11 the back regulation will go so far until the

The instantaneous signal value at output 19 and input 12 corresponds to that at input 10. The linear flanks in the signal ß 'at the input 10 also occur linearly at the output 19, regardless of non-linearities in the Control characteristic of the adjustable resistor (42).

Instead of using the amplifier circuit 15 with

it would also be the regulated feedback ring circuit 16

possible to use an amplifier (44) whose

Self-amplification is regulated directly. The circuit arrangement according to FIG. is for the

fio Honzontal- Austastimpulseinfühnmg added to the image signal E, the signal G according to Figure 2 as a result Starting from the signal G according to Figure 2 may in the same way the horizontal Synchronimpnls omznge- Grooves are oils wherein front and rear shoulder Schwarr- must throw into account. When Wtm- tally-SynchronnnpiiIsemnihrung it is ausreichendi the signal converter 6 without the pulse shaper Jfc first well NRIT the signal comparison circuit ft affid

Amplifier circuit 15 to be used. The horizontal sync pulse, which belongs to a television standard, is fed to input 1 and an (inverted) signal corresponding to the signal G given in FIG. 2 is fed to input 17, and the different DC voltage values are to be adapted. It should be evident that by virtue of the fact that in FIG. 2 given signal B ' the horizontal sync pulse is recorded, a simultaneous introduction of the blanking and sync pulse is possible. Since such a circuit arrangement can be easily implemented according to the above, it will not be discussed further.

The circuit arrangement according to FIG. 1 has been described as being used in a television camera Of course, the circuit arrangement can be used for the entire television set, it is desirable or necessary that there are no defined steep flanks in the horizontal Ai To have (and synchronous) pulses, but Fl with a defined duration. The circuit arrangement is particularly suitable for performing the be; signal processing before the signals signal and image recording apparatus with tapes are fed to disks.

For this purpose 2 sheets of drawings

Claims (8)

Patent claims: 1. Circuit arrangement for inserting pulses with a defined edge duration in a television image signal, in particular in a television camera apparatus, characterized in that a load or synchronizing pulse f £ J is formed in a (first) signal converter (6), which in a first Time range (from tj and to to) a first value (+ Vb) and in a second time range (h to U) a second value (ground potential 0) assumes and that between the first and the second time range and between the second and the first time range each over a certain period of time a defined to the desired extent, z. B. linearly increasing or decreasing. Having edge, and in that this blanking and sync pulse (B ') is used by means of a signal comparison circuit (11) in the television picture signal (£ resp. G) such dan the television picture signal is replaced by the blanking pulse or blanking pulse by the television picture signal as soon as the üneare Fianke of the Austasf- or sync pulse (B ') the value of the television image signal f £ or. C ^ exceeds or falls below. 2. Circuit arrangement according to claim!, Characterized by a switch (4) which is controlled by a switching pulse (D) with steep edges such that it only sends the television image signal outside of a time range approximately coinciding with the second time range (ti to £ 4) (ti to t%) lets through. 3. Sound arrangement according to claim 1 or 2, characterized in that the edges of the blanking or sync pulse (B) by means of a pulse signal (/ ^ controlled current source (21 to 27) are obtained, which have an almost constant charging or Discharge current is supplied to a capacitor (28) in such a way that the voltage on this capacitor forms the pulse with the defined pulse edge duration. 4. Circuit arrangement according to Claim 2 and 3, characterized in that the signal (D) for locking the switch (4) is derived with defined edges by means of a pulse shaper (8) from the horizontal blanking pulse (B) generated by the signal converter (6) will. 5. Circuit arrangement according to claim 4, characterized in that the pulse shaper has a threshold value circuit (34 to 37). 6. Circuit arrangement according to one of the preceding claims, characterized in that the blanking or sync pulse (B ') is used in the television image signal (Ebzw. G) in a signal comparison circuit (11) with two transistors (38, 40), the emitter of which connected to one another and applied to a voltage (+ V <) via a resistor (41), the base of the first transistor (38) carrying the pulse with a defined edge duration and the base of the second transistor (40) carrying the output voltage (from 19) and the collector of the first transistor (38) is connected to a voltage (−V ₁ ) via a resistor (39) and supplies a control signal to an output (13) of the signal comparison circuit (ll). 7. Circuit arrangement according to one of the preceding claims, characterized in: that the output (13) from the collector resistor (39) to the control input (14) of an amplifier circuit (15) is connected, which contains an amplifier (44) with a feedback circuit (16), via which amplifier the television image signal (E ) is fed to the output (19). 8. Circuit arrangement according to claim 7, characterized in that the feedback circuit (16) contains a transistor (42) whose threshold and drain electrodes are connected in parallel to a resistor arranged between the input and output of the amplifier (44) and whose gate electrode is connected to the control input (13,14) is connected.